Soil Carbon and Other Quality Indicators in Managed ... · Bill Keeton - University of Vermont,...
Transcript of Soil Carbon and Other Quality Indicators in Managed ... · Bill Keeton - University of Vermont,...
Soil Carbon and Other Quality Indicators in Managed Northern Forests
Key Findings: Carbon storage in managed forest soils varied greatly with soil depth, elevation, wetness, and time since disturbance and land-use change. Because of this i) effects of harvesting on carbon storage will also likely vary and ii) some sites have a higher potential for future carbon sequestration.
Funding support for this project was provided by the Northeastern States Research Cooperative (NSRC), a partnership of Northern Forest states (New Hampshire, Vermont,
Maine, and New York), in coordination with the USDA Forest Service.http://www.nsrcforest.org
Principal Investigators:
Donald S. Ross and Juilette JuilleratUniversity of Vermont,
Dept. of Plant & Soil ScienceJeffords Hall, 63 Carrigan Drive
Burlington, VT 05405-0082 voice (802) 656-0138e-mail: [email protected]
Sandy WilmotVermont Dept. of Forests, Parks & Recreation
103 South Main Street, 10 NorthWaterbury, VT 05671voice: (802) 241-3307
e-mail: [email protected]
Collaborators:
Caroline Alves and Thom Villars - Natural Resource Conservation ServiceJeff Briggs and Lisa Thornton -Vermont Dept. of Forests, Parks & Recreation
David Brynn - University of Vermont, Green Forestry InitiativeNancy Burt - Green Mountain and Finger Lakes National Forest
Neil Kamman - VT Dept. Environmental Conservation, Water Quality DivisionBill Keeton - University of Vermont, Rubenstein School
Project SummarySoil carbon serves as a major reservoir for carbon storage in forests. Yet there is much unknown about how soil carbon varies with different soil and forest types, and much less known about how managing forests influences positive or negative changes in soil carbon. We have established eighteen reference plots on sites that have sustainable harvesting plans. The sites will serve as pre-harvest references; after re-sampling post-harvest, data can then be analyzed as an aggregate of all sites, or by forest community type, to monitor the overall impact of harvesting on forest soil carbon. These plots will provide the necessary link between the many atmospherically derived forest changes, and those created through forest management.
At each plot location, six subplots were established and soils sampled by depth. Soils were analyzed for carbon, nitrogen, and total mercury. Additional vegetation and physical site characteristics were measured and plots were permanently monumented for future use. Results from pre-harvest sampling showed that more carbon was stored in the soil (59-234 Mg C ha-1) than in live trees (62-180 Mg C ha-1). Carbon storage in the soil appeared to depend on multiple factors, including soil depth, elevation, wetness, and time since disturbance and land-use change. Sites where bedrock was close to the surface stored much less carbon than deeper soils. Higher elevation plots had thicker forest floors, likely as a result of colder temperatures and slower decomposition. Prior land use effects were visible at many sites; remnant stone walls were present and several sites showed evidence of a plow layer, where the organic soil horizons had been mixed with the mineral soil. At the sites with a plow layer (Ap horizon), the forest floor was thinner and earthworms were often found. Coniferous sites hadgenerally, but not consistently, thicker forest floors than deciduous sites. Forest floor carbon had a wider relative range (1.5-34.9 Mg C ha-1) than mineral soil carbon (48-226 Mg C ha-1). The highest mercury concentration (225 ng g-1) was found in the Oe horizons (fermentation layer in the forest floor). However, the highest mercury pools were found in the mineral A horizon because of its higher density.
Harvesting impacts will be most likely strongest on the near-surface soil horizons from physical disturbance and increased light penetration. Because of the intensive baseline sampling, these monitoring plots will be able to detect relatively small changes in forest floor carbon and mercury. Harvesting has already occurred on two of the plots and supportwill be sought for resampling. Results have been presented at regional meetings and disseminated to cooperators and forestry professionals. A publicly-accessible website (http://www.uvm.edu/~soilcrbn/) was created and summarizes key results.
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Background and JustificationChange is occurring in the Northern Forest as a result of human activities. These
activities include regional and global influences of continued acidic deposition, mercury deposition, and climate change. In addition, local forest management practices create an impact, the extent of which may accelerate as increasing pressures are put on local communities to seek alternative energy sources from forests. Science is now showing the positive role forest ecosystems can play in removing and storing excess carbon from the air.
Soil carbon serves as a major reservoir for carbon storage in forests. Yet there is much unknown about how soil carbon varies with different soil and forest types, and much less known about how managing forests influences positive or negative changes in soil carbon. Furthermore, soil quality includes other factors in addition to carbon. Soil quality has a number of definitions but all focus on the sustainability of the ecosystem. One lesson learned from research into the effects of acidic deposition is that we had insufficient baseline data against which to measure change. There are now at least two long-term soil monitoring experiments established in unmanaged forests in Vermont that will be an invaluable resource for studying the effects of regional and global change. In this project, we established soil reference plots in Vermont on actively managed forest lands.
We measured soil carbon pools throughout the soil profile. Results were publicized on a website to promote awareness (http://www.uvm.edu/~soilcrbn).
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Methods• 18 plots on 3 forest types
– 9 northern hardwood– 5 enriched northern hardwood– 4 lowland spruce/fir
• Plot design identical to FIA plots (USDA Forest Service Forest Inventory Analysis)
• 4 vegetation plots• 3 soil sampling locations +
3 more than FIA plots, 600 from each original location
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Methods
Described all vegetation within vegetation plots following the USDA Forest Inventory and Analysis protocol: tree species, diameter at breast height (DBH), tree height, crown and decay class.
Analyzed soil samples for carbon and nitrogen on an elemental analyzer. Archived samples for future analyses.
Collected soil cores for bulk density using diamond-tipped core mounted on a power auger 5
Methods
• Sampled the forest floor separately for each horizon (Oi, Oe, Oa) by cutting the forest floor vertically along 15 x 15 cm frames
• Described soil pits using NRCS criteria
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Results/Project outcomes
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Plot abbr.
PLOT Forest Community Elevation Center
[m]
Average Aspect [deg.]
Average Slope [deg.]
EML Emerald Lake State Park Enriched Northern Hardwood 299 142 21GAR Atlas Partnership 'Garfield' Northern Hardwood 488 97 16GRO Groton State Forest Spruce-Fir 425 245 3HIN Hinesburg Town Forest 'Poor' Northern Hardwood 403 326 5HIR Hinesburg Town Forest 'Rich' Enriched Northern Hardwood 370 349 21JER Jericho Research Forest (UVM) Northern Hardwood 154 269 18MBR Marsh-Billings-Rockefeller National Park Northern Hardwood 397 90 24NFS Green Mountain National Forest Northern Hardwood 493 50 14NIN Coolidge State Forest 'Ninevah' Spruce-Fir 552 182 7PCB Coolidge State Forest 'PCB' Enriched Northern Hardwood 651 193 10SKR Starksboro Town Forest 'Rich' Enriched Northern Hardwood 349 278 24SMB Steam Mill Brook Wildlife Management Area Spruce-Fir 649 254 5SQU Atlas Partnership 'Square' Enriched Northern Hardwood 589 100 15STE Sterling Town Forest (Stowe) 'Hardwoods' Northern Hardwood 528 250 6STK Starksboro Town Forest Northern Hardwood 333 215 13STS Sterlling Town Forest (Stowe) 'Spruce-Fir' Spruce-Fir 94 6WAT Waterworks Northern Hardwood 237 279 18WIL Willoughby State Forest Northern Hardwood 465 79 7
Eighteen sites were sampled representing three forest community types (see map in previous slide for site locations). The table below provides site name and the abbreviation used in all figures.
Site abbreviation key, natural communities and simple characteristics
Results/Project outcomesPercent Basal Area by Tree Species
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
SQU MBR STE JER GAR PCB WIL NFS HIR HIN STK EML STS WAT SKR NIN GRO SMB
Site
TsugacanadensisPicea rubens
Abies balsamea
PopulusgrandidentataFraxinusamericanaQuercus rubra
Prunus serotina
BetulapapyriferaBetulaalleghaniensisFagusgrandifoliaAcer rubrum
Acer saccharum
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The percentage of tree species found at each site are given in the chart to the right. Sugar maple was the dominant species at most of the hardwood sites. Other important species included red maple (A. rubrum), white ash (F. americana), balsam fir (A. balsamea) and red spruce (P. rubens).
Carbon Pools in the Forest Floor(L+F+H or Oi+Oe+Oa)
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5
10
15
20
25
30
35
40
SM
B
PC
B
SQ
U
NIN
GA
R
GR
O
STS WIL
WA
T
NFS
EM
L
STE JE
R
MB
R
HIR
STK HIN
SK
R
Mg
Car
bon
per h
ecta
re
a
cbc
b
a
c
d d
ef
de de
efg efg
fg fg g g g
Different letters indicate statistical differences (P <0.05)
Con
ifer S
ite
Con
ifer S
ite
Con
ifer S
ite
Con
ifer S
ite
Results/Project outcomes
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The pool of carbon in the forest floor varied greatly between sites. Two of the highest pools were found at conifer sites. The lowest pools were at sites that had mineral A horizons rather than organic Oa horizons, likely a legacy of agricultural practices. Because of the numbers of samples taken, statistically significant differences were clear.
Results/Project outcomesCarbon (Organic) Pools in the Soil Profile
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50
100
150
200
250
MB
R
SM
B
GA
R
WIL
NFS NIN
EM
L
STK
PC
B
HIN
STS
STE HIR
JER
SQ
U
SK
R
GR
O
WA
T
Mg
Car
bon
per h
ecta
re
Mineral soil Forest Floor
Total C at EML was 440 Mg/ha
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The mineral soil at all sites held a much greater pool of C than the forest floor. Differences among sites were not as great and statistical differences were few. One high-pH site (Emerald Lake) also had a large pool of inorganic C in its lower horizons, giving it a much higher total C pool than any other site.
Results/Project outcomesBelow and Above-ground Carbon
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50
100
150
200
250
MB
R
SM
B
NIN
WIL
EM
L
NFS
GA
R
STK
STS HIN
PC
B
STE HIR
JER
SQ
U
GR
O
SK
R
WA
T
Mg
Car
bon
per h
ecta
re
Belowground C Aboveground C
Aboveground only includes live trees
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The soil, belowground, pool of C was usually higher than the aboveground pool of C found in live trees. There did not appear to be any relationship between these two pools.
Results/Project outcomesFactors affecting soil C accumulation:A number of controlling factorson soil C pools were evident. The legacy of agriculture appearsto have been the strongest. • Soil depth• Elevation
– Lower soil temperature at higher elevation
– Decomposition slowed more than production• Wetness (drainage)• Time since disturbance• Time since land-use change (farm to forest)
Stone Wall at NIN Coolidge State Forest
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Results/Project outcomesMercury
• Average mercury concentrations for the sampled horizons:– 73 ng/g for the Oi– 225 ng/g for the Oe– 181 ng/g for A/Oa horizons
• Sites either had an A horizon or an Oa horizon. Although mercury concentrations were lower in the A horizon, the density of the A horizon was much higher—resulting in higher mercury pools.
• Therefore, factors that affected the presence or absence of the A horizon (and the thickness of the forest floor) also affected the upper-soil mercury pools. 13
OutreachWebsite:http://www.uvm.edu/~soilcrbn/
Plant and Soil Science Department Newsletter: The Tiller, Volume 4, Issue 1, 2009
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Implications and applicationsin the Northern Forest region
• Some lower elevation sites, such at the Waterworks property, are relatively low in soil carbon and thus have a high potential for future carbon sequestration.
• Because there was a wide variation in carbon in the upper soil horizons (the zone most susceptible to harvesting impacts) disturbance effects may be more dramatic at some sites—those with high carbon pools in the forest floor.
• Rich northern hardwood sites may not be favorable locations for increased carbon sequestration because shallower soils are common and carbon turnover may be faster.
• Mercury concentrations were highest in the organic horizons but mercury pools were higher in denser, mineral horizons. Therefore, sites with thin forest floors and A horizons actually have greater amounts of mercury in the near-surface layer.
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Future directions
• Re-sample after harvest– Changes in carbon storage in soils depending on intensity of
harvest– Changes in mercury deposition and concentration in the
forest floor
• Influence of earthworms on forest floor depth
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List of products• Publications
– Juillerat J. I., in preparation expected ready 12/2010• Theses
– Juillerat J. I., Influence of Forest Composition on Mercury Deposition in Litterfall and Subsequent Accumulation in Soils, December 2010
• Conference Presentations – ECANUSA, 2010
• Poster Presentations– Vermont Monitoring Cooperative, 2008– University of Vermont Student Day, 2009– American Geophysical Union, 2009, 2010– Goldschmidt, 2010
• Newsletter– Plant and Soil Science Department Newsletter, The Tiller,
Volume 4, Issue 1, 2009• Website
– http://www.uvm.edu/~soilcrbn/17